Display apparatus and controlling method thereof

ABSTRACT

A display apparatus and a controlling method are provided. The display apparatus includes a communication interface configured to receive a plurality of image signals from a plurality of external devices, a display configured to display a screen including a plurality of regions respectively corresponding to each of the plurality of image signals, and a processor configured to, in response to a directional touch gesture being input on the display, select a region from among the plurality of regions based on a direction of a directional touch gesture and control the display to display the selected region as a full screen.

CROSS-REFERENCE TO RELATED APPLICATION

This application claims priority from Korean Patent Application No.10-2016-0070116, filed in the Korean Intellectual Property Office onJun. 7, 2016, the disclosure of which is incorporated herein byreference in its entirety.

BACKGROUND 1. Field

Apparatuses and methods consistent with exemplary embodiments relate toa display apparatus, and more particularly, to a display apparatus forselecting one screen among screens respectively corresponding to aplurality of image signals, and a controlling method thereof.

2. Related Art

A display apparatus may be connected to an external device and displayan image signal input from the external device on the display unit. Inthe past, in order to control what is displayed on the display unit, theuser had to input a control command directly from an external devicethat transmits an image signal. As the remote controller has developed,the user can remotely input the control command to the external device.However, this requires an additional remote control to control theexternal device.

In order to overcome the inconvenience, a display apparatus in which atouch module is disposed on the display unit has been developed. A usercan control a remote external device without an additional device byinputting a touch command through the touch module in the vicinity ofthe display apparatus.

On the other hand, as display units become increasingly larger, a usermay recognize individual contents, even if a plurality of contents aredisplayed. Generally, a user can select one content by selecting an areawhere content to be selected is displayed. However, because the displayunit is larger than the user, the user's hand may not reach the contentarea to be selected. Further, there is an inconvenience that the userhas to move a certain distance in order to select content on theopposite side where the user is located. Therefore, there is a need fora technique that allows convenient selection of displayed content.

SUMMARY

One or more exemplary embodiments provide a display apparatus capable ofconveniently selecting one of screens corresponding to a plurality ofimage signals, and a controlling method thereof.

According to an aspect of an exemplary embodiment, there is provided adisplay apparatus including: a communication interface configured toreceive a plurality of image signals from a plurality of externaldevices; a display configured to display a screen including a pluralityof regions respectively corresponding to each of the plurality of imagesignals; and a processor configured to, in response to a directionaltouch gesture being input on the display, select a region from among theplurality of regions based on a direction of the directional touchgesture and control the display to display the selected region as a fullscreen.

The processor may be further configured to not consider a starting pointof the directional touch gesture.

The processor may be further configured to, in response to a touchcommand being input while the selected region is the displayed as thefull screen, control the communication interface to transmit the touchcommand to an external device that transmits an image signal of theplurality of image signals corresponding to the full screen.

The processor may be further configured to calculate the direction ofthe directional touch gesture based on a coordinate of a starting pointof the directional touch gesture and a coordinate of an ending point ofthe directional touch gesture.

The processor may be further configured to determine an x-axis valuebased on a difference between an x-coordinate of the starting point ofthe directional touch gesture and an x-coordinate of the ending point ofthe directional touch gesture, determine a y-axis value based on adifference between a y-coordinate of the starting point of thedirectional touch gesture and a y-coordinate of the ending point of thedirectional touch gesture, and select the region based on the x-axisvalue and the y-axis value.

The processor may be further configured to, in a state in which theplurality of regions includes three regions respectively arranged on aleft side, a right side and a first middle between the left side and theright side, in response to a touch gesture for selecting one point beinginput, select an area arranged in the first middle, in response to thex-axis value being positive, select an area arranged on the left side,and in response to the x-axis value being negative, select a regionarranged on the right side; and in a state in which the plurality ofregions includes three regions arranged on an upper side, a lower sideand a second middle between the upper side and the lower side, inresponse to the touch gesture for selecting the one point being input,select a region arranged in the second middle, in response to the y-axisvalue being positive, select a region arranged on the upper side, and inresponse to the y-axis value being negative, select a region arranged onthe lower side.

The processor may be further configured to, in a state in which theplurality of images includes four regions respectively arranged on anupper left portion, an upper right portion, a lower left portion, and alower right portion, in response to the x-axis value being positive andthe y-axis value being positive, select a region arranged on the upperleft portion, in response to the x-axis value being negative and they-axis value being positive, select a region arranged on the upper rightportion, in response to the x-axis value being positive and the y-axisvalue being negative, select a region arranged on the lower leftportion, and in response to the x-axis value being negative and they-axis value being negative, select a region arranged on the lower rightportion.

The processor may be further configured to select the region based on amoving length of the directional touch gesture.

The processor may be further configured to, in a state in which theplurality of regions are arranged in a horizontal arrangement format ina left direction and a right direction and the x-axis value is positive,in response to an x-axis moving length being less than a first thresholdvalue, select a first region arranged on a rightmost side, in responseto the x-axis moving length being greater than the first threshold valueand less than a second threshold value, select a second region adjacentto a left side of the first region, and in response to the x-axis movinglength being greater than an (n−1) threshold value and less than an nthreshold value, select an n region adjacent to a left side of a (n−1)region; and in a state in which a value in the x-axis direction of thedirectional touch gesture is negative, in response to an x-axis movinglength being less than the first threshold value, select the n region,in response to the x-axis moving length being greater than the firstthreshold value and less than the second threshold value, select the n−1region adjacent, and in response to the x-axis moving length greaterthan the (n−1) threshold value and less than the n threshold value,select the second region.

According to an aspect of another exemplary embodiment, there isprovided a method of controlling method of a display apparatus, themethod including: receiving a plurality of image signals from aplurality of external devices; displaying a screen including a pluralityof regions respectively corresponding to each of the plurality of imagesignals; in response to a directional touch gesture being input on thedisplay, selecting a region from among the plurality of regions based ona direction of the directional touch gesture; and displaying theselected region as a full screen.

The selecting may not include considering a starting point of thedirectional touch gesture.

The method may further include: in response to a touch command beinginput while the selected region is the displayed as the full screen,transmitting the touch command to an external device that transmits animage signal of the plurality of signals corresponding to the fullscreen.

The selecting may include calculating the direction of the directionaltouch gesture based on a coordinate of a starting point of thedirectional touch gesture and an ending point of the directional touchgesture.

The selecting may include determining an x-axis value based on adifference between an x-coordinate of the starting point of thedirectional touch gesture and an x-coordinate of the ending point of thedirectional touch gesture, determining a y-axis value based on adifference between a y-coordinate of the starting point of thedirectional touch gesture and a y-coordinate of the ending point of thetouch directional gesture, and selecting the region based on the x-axisvalue and the y-axis value.

The selecting may include, in a state in which the plurality of regionsincludes three regions respectively arranged on a left side, a rightside and a first middle between the left side and the right side, inresponse to a touch gesture for selecting one point being input,selecting an area arranged in the first middle, in response to thex-axis value being positive, selecting an area arranged on the leftside, and in response to the x-axis value being negative, selecting aregion arranged on the right side; and in a state in which the pluralityof regions includes three regions arranged on an upper side, a lowerside and a second middle between the upper side and the lower side, inresponse to the touch gesture for selecting the one point being input,selecting a region arranged in the second middle, in response to they-axis value being positive, selecting a region arranged on the upperside, and in response to the y-axis value being negative, selecting aregion arranged on the lower side.

The selecting may include, in a state in which the plurality of imagesincludes four regions respectively arranged on an upper left portion, anupper right portion, a lower left portion, and a lower right portion, inresponse to the x-axis value being positive and the y-axis value beingpositive, selecting a region arranged on the upper left portion, inresponse to the x-axis value being negative and the y-axis value beingpositive, selecting a region arranged on the upper right portion, inresponse to the x-axis value being positive and the y-axis value beingnegative, selecting a region arranged on the lower left portion, and inresponse to the x-axis value being negative and the y-axis value beingnegative, selecting a region arranged on the lower right portion.

The selecting may include selecting the region based on a moving lengthof the directional touch gesture.

The selecting may include, in a state in which the plurality of regionsare arranged in a horizontal arrangement format arranged in a leftdirection and a right direction and the x-axis value is positive, inresponse to an x-axis moving length being less than a first thresholdvalue, selecting a first region arranged on a rightmost side, inresponse to the x-axis moving length being greater than the firstthreshold value and less than a second threshold value, selecting asecond region adjacent to a left side of the first region, and inresponse to the x-axis moving length being greater than an (n−1)threshold value and less than an n threshold value, selecting an nregion adjacent to a left side of a (n−1) region; and in a state inwhich a value in the x-axis direction of the directional touch gestureis negative, in response to an x-axis moving length being less than thefirst threshold value, selecting the n region, in response to the x-axismoving length being greater than the first threshold value and less thanthe second threshold value, selecting the n−1 region, and in response tothe x-axis moving length being greater than the (n−1) threshold valueand less than the n threshold value, selecting the second region.

BRIEF DESCRIPTION OF THE DRAWINGS

The above and other aspects will become more apparent from the followingdescription of exemplary embodiments, with reference to the accompanyingdrawings, in which:

FIG. 1 is a view for explaining a display system according to anexemplary embodiment;

FIG. 2 is a block diagram of a display apparatus according to anexemplary embodiment;

FIG. 3 is a view for explaining a detailed configuration of a displayapparatus according to an exemplary embodiment;

FIGS. 4A and 4B are views for explaining a first exemplary embodimentfor selecting one of a plurality of regions;

FIGS. 5A and 5B are views for explaining a second exemplary embodimentfor selecting one of a plurality of regions;

FIGS. 6A and 6B are views for explaining a third exemplary embodimentfor selecting one of a plurality of regions;

FIGS. 7A and 7B are views for explaining a fourth exemplary embodimentfor selecting one of a plurality of regions;

FIGS. 8A and 8B are views for explaining a fifth exemplary embodimentfor selecting one of a plurality of regions;

FIGS. 9A and 9B are views for explaining a sixth exemplary embodimentfor selecting one of a plurality of regions;

FIGS. 10A and 10B are views for explaining a seventh exemplaryembodiment for selecting one of a plurality of regions;

FIGS. 11A and 11B are views for explaining an eighth exemplaryembodiment for selecting one of a plurality of regions;

FIGS. 12A and 12B are views for explaining a ninth exemplary embodimentfor selecting one of a plurality of regions; and

FIG. 13 is a flowchart illustrating a control method of the displayapparatus according to an exemplary embodiment.

DETAILED DESCRIPTION

Exemplary embodiments will now be described in detail with reference tothe accompanying drawings. The exemplary embodiments described hereincan be variously modified. Aspects of exemplary embodiments aredescribed in the drawings and may be described in detail in the detaileddescription. It should be understood, however, that the specificexemplary embodiments illustrated in the accompanying drawings are onlyintended to facilitate understanding of the various exemplaryembodiments. Accordingly, it is to be understood that the technical ideais not limited by the specific exemplary embodiments illustrated in theaccompanying drawings, but includes all equivalents or alternativesfalling within the spirit and scope of the invention. In the followingdescription, a detailed description of known functions andconfigurations incorporated herein will be omitted when it may make thesubject matter of the present disclosure rather unclear.

Terms including ordinals, such as first, second, etc., may be used todescribe various elements, but such elements are not limited to theabove terms. The above terms are used only for the purpose ofdistinguishing one component from another.

In this specification, the terms “comprise”, “include”, “have”, and thelike are intended to specify that there are stated features, numbers,steps, operations, elements, parts or combinations thereof, and shouldnot be construed to preclude the presence or addition of one or moreother features, integers, steps, operations, elements, parts, orcombinations. It is to be understood that when an element is referred toas being “connected” or “accessed” to another element, it may bedirectly connected or accessed to the other element, but it should beunderstood that there may be other components in between. On the otherhand, when an element is referred to as being “directly connected” or“directly accessed” to another element, it should be understood thatthere are no other elements in between.

The terms “module” or “unit” for components used in the presentspecification performs at least one function or operation. And a“module” or a “unit” may perform functions or operations by hardware,software, or a combination of hardware and software. Also, a pluralityof “modules” or a plurality of “units” other than “modules” or “units”that are to be performed in a specific hardware or performed in at leastone processor may be integrated into at least one module.

It is to be understood that the singular forms “a,” “an,” and “the”include plural referents unless the context clearly dictates otherwise.

FIG. 1 is a view for explaining a display system according to anexemplary embodiment.

Referring to FIG. 1, a display system includes a display apparatus 100and at least one external device 200-1, 200-2, 200-3, and 200-4. Forexample, the display apparatus 100 may include an electronic blackboard,a television (TV), a kiosk, a video wall, a media pole, and the like.The external devices 200-1, 200-2, 200-3, and 200-4 may include a smartphone, a notebook computer, a personal digital assistant (PDA), aportable media player (PMP), a navigation device, a slate PC, a tabletPC, an ultrabook, a wearable device, and the like.

The external devices 200-1, 200-2, 200-3, and 200-4 may be connected tothe display apparatus 100 by wire or wirelessly. Each of the externaldevices 200-1, 200-2, 200-3, and 200-4 can transmit an image signal tothe display apparatus 100. The display apparatus 100 can mix andreconstruct the respective image signals received from the respectiveexternal devices 200-1, 200-2, 200-3, and 200-4. That is, the displayapparatus 100 may adjust each input image signal to a predeterminedresolution in consideration of the number of input image signals, andrearrange the image signals into a single screen by arranging the inputimage signals according to a predetermined format. In one exemplaryembodiment, when the number of input image signals is four, the displayapparatus 100 separates the four regions of the upper left region, thelower left region, the upper right region, and the lower right region,and may output the images of the received image signals to each area.Alternatively, the display apparatus 100 may divide four regionshorizontally and output an image of the received image signal in eachregion. Alternatively, the display apparatus 100 may divide four regionsvertically and output an image of the received image signal in eachregion. The display apparatus 100 can change the arrangement formataccording to the user's selection and adjust the resolution of the inputimage signal according to the selected arrangement format to output animage in a predetermined area.

The display apparatus 100 may include a touch module receiving a touchcommand. The display of the display apparatus 100 may have a mutuallayer structure with the touch module or may be integrally formed. Thedisplay of the display apparatus 100 may function as an input interfacefor receiving a command from the user through the touch module and anoutput interface for outputting an image.

The display apparatus 100 may receive a directional touch gesture on thedisplay. The display apparatus 100 can select one of the plurality ofareas based on the direction of the input touch gesture. A specificprocess of selecting one area based on the input touch gesture will bedescribed below.

The display apparatus 100 displays an image of one selected area in fullscreen. The display apparatus 100 may display an image of one area onthe full screen, and then receive a touch gesture through the display.The input touch gesture may be a command to control a selected externaldevice to transmit an image signal corresponding to an image displayedon the full screen. The display apparatus 100 may transmit a commandcorresponding to the input touch gesture to the selected externaldevice. That is, the selected external device refers to an externaldevice that transmits an image signal corresponding to an imageoutputted on the full screen. The display apparatus 100 may transmit theinput value of the touch gesture to the directly selected externaldevice and may determine the command of the input touch gesture andtransmit the determined command value to the selected external device.The selected external device can be controlled in accordance with acontrol command received from the display apparatus 100.

For example, the display apparatus 100 may display an image of one areaon a full screen, and receive a touch gesture corresponding to a commandto switch the screen through a display. The display apparatus 100 cantransmit the input value of the touch gesture to the selected externaldevice and analyze the inputted touch gesture to determine that it is ascreen switching command. The display apparatus 100 may transmit a valuecorresponding to the screen switching command to the selected externaldevice. The selected external device can directly or indirectly receivea screen switching command from the display apparatus 100. When theselected external device determines the screen switching command, thecurrently displayed screen can be switched to another screen. The usermay control the selected external device through the display apparatus100 without directly inputting the command to the selected externaldevice for transmitting the image signal.

In the following, the display apparatus 100 will be described based on ablock diagram of the display apparatus 100.

FIG. 2 is a block diagram of a display apparatus according to anexemplary embodiment.

Referring to FIG. 2, the display apparatus 100 includes a communicationinterface 110, a processor 120, and a display 130.

The communication interface 110 receives a plurality of image signalsfrom a plurality of external devices. The communication interface 110may receive an image signal from one external device. For example, thecommunication interface 110 may communicate with an external deviceusing a communication interface, such as Bluetooth, infraredcommunication, Ultra Wideband (UWB), ZigBee, Wi-Fi, Wireless LAN (WLAN),Digital Living Network Alliance (DLNA), Wireless Broadband (WiBro), HighSpeed Uplink Packet Access (HSDPA), Long Term Evolution (LTE), and thelike. Alternatively, the communication interface 110 may communicatewith an external device by wire.

The display 130 displays a screen including a plurality of regionscorresponding to each of the plurality of image signals. The display 130may be a general size display used for a notebook computer, a monitor, aTV, or the like, and may be a display of which width or height is longerthan a person's height. The display 130 may include a touch module. Thetouch module may be implemented integrally with the display 130 and maybe implemented separately from the display 130 and disposed on thedisplay 130. The display 130 including the touch module may receive atouch gesture.

When a directional touch gesture is input on the display 130, theprocessor 120 selects one of the plurality of regions based on thedirection of the touch gesture. When the processor 120 selects one area,one area may be selected based only on the direction of the touchgesture. That is, the processor 120 does not consider the starting pointof the directional touch gesture.

The processor 120 may calculate the direction of the touch gesture usingthe relative coordinates of the starting point and the ending point ofthe directional touch gesture. For example, the processor 120 maydetermine a value in the x-axis direction based on the differencebetween the x-coordinates of the starting point and the ending point ofthe touch gesture, and determine a value in the y-axis direction basedon the difference between the y-coordinates of the starting point andthe ending point of the touch gesture. Then, the processor 120 mayselect one of a plurality of regions in a corresponding direction basedon the determined values of the x-axis direction and the y-axisdirection.

Meanwhile, the processor 120 may select one of the plurality of regionsby considering the moving length of the directional touch gesture. Forexample, when the direction of the touch gesture is the left side andthere are a plurality of regions located on the left side, the processor120 may select a first region if the moving length of the touch gestureis less than a first threshold value, a second region if the movinglength of the touch gesture is greater than the first threshold valueand less than a second threshold value, and a third region if the movinglength of the touch gesture is greater than or equal to the secondthreshold value. Specific exemplary embodiments will be described below.

The processor 120 then controls the display 130 to display an image ofthe selected one region in full screen. In addition, when receiving atouch command on the displayed full screen, the processor 120 maycontrol the communicator to transmit the touch command to an externaldevice that transmits an image signal corresponding to the full screen.

FIG. 3 is a view for explaining a detailed configuration of a displayapparatus according to an exemplary embodiment.

Referring to FIG. 3, the processor 120 of the display apparatus 100 mayinclude an input image mixing block 121, an image interface 122, agesture determination block 123, and an interface switch block 124.

The input image mixing block 121 may receive a plurality of imagesignals from a plurality of external devices, mixes the received imagesignals, and reconstructs them into one screen. The plurality ofexternal devices may transmit the respective image signals to thedisplay apparatus 100. The display apparatus 100 may receive therespective image signals through the wired/wireless communicationinterface 110. Each of the received image signals may be transmitted tothe input image mixing block 121 of the processor 120. The input imagemixing bock 121 may mix the respective image signals based on apredetermined resolution and a predetermined format. The meaning ofmixing does not mean that each video signal is overlapped, but meansthat one image is divided into a plurality of regions and an imagecorresponding to each image signal is arranged in each region. In oneexemplary embodiment, when there are four input image signals, the inputimage mixing block 121 may divide one screen into an upper left region,a lower left region, an upper right region, and a lower right region,and may arrange an image corresponding to an image signal A in the upperleft region, an image corresponding to an image signal B in the upperright region, an image corresponding to an image signal C in the lowerleft region, and an image corresponding to an image signal D in thelower right region. The input image mixing block 121 may switch toanother format according to a user's input, and may change the size ofeach area. In addition, the input image mixing block 121 may displayimages of appropriate resolution in the respective regions according tothe resolution of the input image signal, the number of divided regions,the shape of the divided regions, and the like.

The image interface 122 may transfer the screen reconstructed in theinput image mixing block 121 to the display 130. The display 131 mayinclude a touch module to recognize a touch gesture input on thedisplay. The display 130 may receive a directional touch gesture.

The gesture determination block 123 may determine the touch gestureinput on the display. A full screen may include four corner coordinatepoints. For example, a display at HD resolution may have a resolution of1920×1080. Therefore, the coordinates of (0, 0) may be set at the upperleft corner, (1919, 0) at the upper right corner, (0, 1079) at the lowerleft corner, and (1919, 1079) at the lower right corner. In oneexemplary embodiment, the gesture determination block 123 may determinethe difference between the starting point of the touch gesture and thecoordinates of each corner. In addition, the gesture determination block123 may determine the difference between the ending point of the touchgesture and the coordinates of each corner. The gesture determinationblock 123 may determine that the touch gesture has moved in a cornerdirection where the difference between the coordinates of the endingpoint of the touch gesture is smaller than the difference between thecoordinates of the starting point of the touch gesture. The processor120 may then select a region associated with the determined corner.

Specifically, when the starting coordinates of the touch gesture is(959, 539), the starting coordinates of the touch gesture differs fromthe coordinates of the upper left corner by (959, 539), differs from thecoordinates of the upper right corner by (960 539), differs from thelower left corner by (959, 540), and differs from the coordinates of thelower right corner by (960, 540). If the touch gesture moves in theupper left direction and the ending coordinate is (353, 278), the endingcoordinate of the touch gesture differs from the upper left cornercoordinate by (353, 278), differs from the upper right corner coordinateby (1566, 278), differs from the lower left corner coordinate by (353,801), and differs from the lower right corner coordinate by (1566, 801).Since the increase/decrease of the difference between the cornercoordinates and the touch gesture coordinates is calculated according tothe movement of the touch gesture, all the coordinate values can becalculated as absolute values.

Considering the variation in the difference from each corner coordinatedue to the movement of the touch gesture, in the case of the upper rightcorner, both the difference of x-axis coordinate and the difference ofy-axis coordinate are reduced. Therefore, the gesture determinationblock 123 may determine that the touch gesture has moved in the upperleft direction. The moving direction of the touch gesture may bedetermined using the difference between the coordinates of the startingpoint of the touch gesture and the coordinates of the ending pointirrespective of the corner coordinates. Then, the processor 120 mayselect an A image arranged in the upper left region. The processor maydisplay the A image in full screen.

Meanwhile, the interface switch 124 may connect the processor with anexternal device corresponding to a selected one of a plurality ofregions. That is, the interface switch 124 may transmit the command ofthe touch gesture determined by the gesture determination block 123 toan external device A corresponding to the A image. Alternatively, theinterface switch 124 may bypass the gesture determination block 123 andtransmit an input value of a touch gesture inputted on the display tothe external device.

Hereinbelow, a process of selecting one of a plurality of regions bydetermining the direction and moving distance of a directional touchgesture will be described.

FIGS. 4A and 4B are views for explaining a first exemplary embodimentfor selecting one of a plurality of regions.

Referring to FIG. 4A, a screen including a plurality of regionscorresponding to a plurality of image signals is shown. There are fourimage signals, and the A image signal may correspond to the upper leftregion, the B image signal to the upper right region, the C video signalto the lower left region, and the D video signal to the lower rightregion. A′ is the upper left corner, B′ is the upper right corner, C′ isthe lower left corner, and D′ is the lower right corner. The touchgesture on the display may be moved in the upper left direction. Thestarting position of the touch gesture is independent of the regionselection.

Referring to FIG. 4B, a table for explaining a method of determining themoving direction of the touch gesture is shown.

In one exemplary embodiment, the direction of the touch gesture may bedetermined using the relative coordinate difference between the startingand ending points of the touch gesture. The x-coordinate may decrease asthe touch gesture moves in the left direction, and the x-coordinate mayincrease as it moves in the right direction. When the touch gesturemoves in the upward direction, the y-coordinate decreases. When thetouch gesture moves in the downward direction, the y-coordinateincreases. The table shown in FIG. 4B is a table showing the differencefrom the ending coordinates based on the starting coordinates. As shownin FIG. 4A, when the touch gesture moves in the upper left direction,the x-coordinate and the y-coordinate are decreased based on thestarting coordinates of the touch gesture. When the difference from theending coordinate is calculated based on the starting coordinate, thedifference (p) of the x-coordinate of the touch gesture and thedifference (q) of the y-coordinate are all positive. The displayapparatus 100 may, if the difference between the x-coordinate and they-coordinate is positive, determine that the touch gesture has moved inthe upper left direction and select the region of the A image signal inthe upper left direction.

When the touch gesture moves in the upper right direction, thex-coordinate increases and the y-coordinate decreases based on thestarting coordinates of the touch gesture. When the difference from theending coordinate is calculated based on the starting coordinate, thedifference (p) of the x-coordinate of the touch gesture is negative andthe difference (q) of the y-coordinate is positive. The displayapparatus 100 may determine that the touch gesture has moved in theupper right direction and may select the region of the B image signal inthe upper right direction if the difference in x-coordinate is negativeand the difference in y-coordinate is positive.

When the touch gesture moves in the lower left direction, thex-coordinate decreases and the y-coordinate increases based on thestarting coordinates of the touch gesture. When the difference from theending coordinate is calculated based on the starting coordinate, thedifference (p) of the x-coordinate of the touch gesture is positive andthe difference (q) of the y-coordinate is negative. The displayapparatus 100 may determine that the touch gesture has moved in thelower left direction and may select the region of the C image signal inthe lower left direction if the difference in x-coordinate is positiveand the difference in y-coordinate is negative.

When the touch gesture moves in the lower right direction, thex-coordinate and the y-coordinate are increased based on the startingcoordinates of the touch gesture. When the difference from the endingcoordinate is calculated based on the starting coordinate, thedifference (p) of the x-coordinate of the touch gesture and thedifference (q) of the y-coordinate are all negative. The displayapparatus 100 may determine that the touch gesture has moved in thelower right direction and may select the region of the D image signal inthe lower right direction if the difference in x-coordinate is negativeand the difference in y-coordinate is negative.

That is, the display apparatus 100 may determine a value in the x-axisdirection based on the difference between the x-coordinates of thestarting point and the ending point of the touch gesture, and determinea value in the y-axis direction based on the difference between they-coordinates. The display apparatus 100 may select a region of acorresponding direction of the plurality of regions based on thedetermined values of the x-axis direction and the y-axis direction.

As another exemplary embodiment, the display apparatus 100 may determinethe direction of the touch gesture based on the change in the differencebetween the corner coordinates and the touch gesture coordinatesaccording to the movement of the touch gesture. The difference betweenthe corner coordinates and the coordinates of the touch gesturecoordinate can be expressed as an absolute value. As described above,when the touch gesture moves, the difference between the coordinates ofthe touch gesture and the corner coordinates close to the movingdirection is reduced. That is, the display apparatus 100 may determinethat the touch gesture moves toward a corner in the direction in whichthe difference between the coordinates of the touch gesture and thecorner coordinates decreases. For example, in the case where A′coordinate is (0, 0), B′ coordinate is (1000, 0), C′ coordinate is (0,1000), and D′ coordinate is (1000, 1000) and the starting coordinates ofthe touch gesture are (500, 500), when the touch gesture moves in theupper left direction, the x and y coordinates of the touch gesturedecrease. Accordingly, the difference between the x-axis value andy-axis value between the A′ coordinate and the touch gesture coordinatedecreases. The display apparatus 100 may determine that the touchgesture moves in the A corner direction. If the touch gesture moves inthe upper right direction, the x-coordinate of the touch gestureincreases and the y-coordinate decreases. Accordingly, the differencebetween the x-axis value and y-axis value between the B′ coordinate andthe touch gesture coordinate decreases. The display apparatus 100 maydetermine that the touch gesture moves in the B corner direction.

If the touch gesture moves in the lower left direction, the x-coordinateof the touch gesture decreases and the y-coordinate increases.Accordingly, the difference between the x-axis value and y-axis valuebetween the C′ coordinate and the touch gesture coordinate decreases.The display apparatus 100 may determine that the touch gesture moves inthe C corner direction. If the touch gesture moves in the lower rightdirection, the x and y coordinates of the touch gesture increase.Accordingly, the difference between the x-axis value and y-axis valuebetween the D′ coordinate and the touch gesture coordinate decreases.The display apparatus 100 may determine that the touch gesture moves inthe D corner direction.

FIGS. 5A and 5B are views for explaining a second exemplary embodimentfor selecting one of a plurality of regions.

Referring to FIG. 5A, a screen including a plurality of regionscorresponding to a plurality of image signals is shown. There are twoimage signals, and the C image signal may correspond to the left region,and the D image signal may correspond to the right region. K is theupper left corner, L is the upper right corner, M is the lower leftcorner, and N is the lower right corner.

Referring to FIG. 5B, a table for explaining a method of determining themoving direction of the touch gesture is shown.

In one exemplary embodiment, the direction of the touch gesture may bedetermined using the relative coordinate difference between the startingand ending points of the touch gesture. The table shown in FIG. 5B is atable showing the difference from the ending coordinates based on thestarting coordinates. When the touch gesture moves in the leftdirection, the x-coordinate decreases based on the starting coordinatesof the touch gesture. When the difference from the ending coordinate iscalculated based on the starting coordinate, the difference (p) of thex-coordinate of the touch gesture is positive. If the difference in xcoordinate is positive, the display apparatus 100 may determine that thetouch gesture has shifted to the left side, and select a region of the Cimage signal in the left direction. Since the display screen is dividedinto a left region and a right region, there is no influence on they-coordinate.

When the touch gesture moves in the right direction, the x-coordinateincreases based on the starting coordinates of the touch gesture. Whenthe difference from the ending coordinate is calculated based on thestarting coordinate, the difference (p) of the x-coordinate of the touchgesture is negative. If the difference in x coordinate is negative, thedisplay apparatus 100 may determine that the touch gesture has shiftedto the right side, and select a region of the D image signal in theright direction.

As another exemplary embodiment, the display apparatus 100 may determinethe direction of the touch gesture based on the change in the differencebetween the corner coordinates and the touch gesture coordinatesaccording to the movement of the touch gesture. The difference betweenthe corner coordinates and the coordinates of the touch gesturecoordinate can be expressed as an absolute value. As described above,when the touch gesture moves, the difference between the coordinates ofthe touch gesture and the corner coordinates close to the movingdirection is reduced. That is, the display apparatus 100 may determinethat the touch gesture moves toward a corner in the direction in whichthe difference between the coordinates of the touch gesture and thecorner coordinates decreases. For example, in the case where K-cornercoordinate is (0, 0), L-corner coordinate is (1000, 0), M-cornercoordinate is (0, 1000), and N-corner coordinate is (1000, 1000) and thestarting coordinates of the touch gesture are (500, 500), when the touchgesture moves in the left direction, the x-coordinate of the touchgesture decrease. Accordingly, the difference between the x-axis valuesbetween the K-corner coordinates or the M-corner coordinates and thetouch gesture coordinates decreases. The display apparatus 100 maydetermine that the touch gesture moves in the direction of the K-corneror the M-corner. If the touch gesture moves to the right, thex-coordinate of the touch gesture increases. Accordingly, the differencebetween the x-axis values between the L-corner coordinates or theN-corner coordinates and the touch gesture coordinates decreases. Thedisplay apparatus 100 may determine that the touch gesture moves in thedirection of the L-corner or the N-corner.

FIGS. 6A and 6B are views for explaining a third exemplary embodimentfor selecting one of a plurality of regions.

Referring to FIG. 6A, a screen including a plurality of regionscorresponding to a plurality of image signals is shown. There are twoimage signals, and the C image signal may correspond to the upperregion, and the D image signal may correspond to the lower region. K isthe upper left corner, L is the upper right corner, M is the lower leftcorner, and N is the lower right corner.

Referring to FIG. 6B, a table for explaining a method of determining themoving direction of the touch gesture is shown.

In one exemplary embodiment, the direction of the touch gesture may bedetermined using the relative coordinate difference between the startingand ending points of the touch gesture. When the touch gesture moves inthe upward direction, the y-coordinate decreases based on the startingcoordinates of the touch gesture. When the difference from the endingcoordinate is calculated based on the starting coordinate, thedifference (q) of the y-coordinate of the touch gesture is positive. Ifthe difference in y-coordinate is positive, the display apparatus 100may determine that the touch gesture has shifted in the upwarddirection, and select a region of the C image signal in the upwarddirection. Since the display screen is divided into an upper region anda lower region, there is no influence on the x-coordinate.

When the touch gesture moves in the downward direction, the y-coordinateincreases based on the starting coordinates of the touch gesture. Whenthe difference from the ending coordinate is calculated based on thestarting coordinate, the difference (q) of the y-coordinate of the touchgesture is negative. If the difference in y-coordinate is negative, thedisplay apparatus 100 may determine that the touch gesture has shiftedin the downward direction, and select a region of the D image signal inthe downward direction.

As another exemplary embodiment, the display apparatus 100 may determinethe direction of the touch gesture based on the change in the differencebetween the corner coordinates and the touch gesture coordinatesaccording to the movement of the touch gesture. When the touch gesturemoves, the difference between the coordinate of the touch gesture andthe corner coordinate near the moving direction is reduced. That is, thedisplay apparatus 100 may determine that the touch gesture moves towarda corner in the direction in which the difference between thecoordinates of the touch gesture and the corner coordinates decreases.For example, if the touch gesture moves in the upward direction, they-coordinate of the touch gesture decreases. Accordingly, the differencebetween the y-axis values between the K-corner coordinates or theL-corner coordinates and the touch gesture coordinates decreases. Thedisplay apparatus 100 may determine that the touch gesture moves in thedirection of the K-corner or the L-corner. If the touch gesture moves inthe downward direction, the y-coordinate of the touch gesture increases.Accordingly, the difference between the y-axis values between theM-corner coordinates or the N-corner coordinates and the touch gesturecoordinates decreases. The display apparatus 100 may determine that thetouch gesture moves in the direction of the M-corner or the N-corner.

FIGS. 7A and 7B are views for explaining a third exemplary embodimentfor selecting one of a plurality of regions.

Referring to FIG. 7A, a screen including a plurality of regionscorresponding to a plurality of image signals is shown. There are threeimage signals, and the C image signal may correspond to the left region,the B image signal may correspond to the middle region, and the D imagesignal may correspond to the right region.

Referring to FIG. 7B, a table for explaining a method of determining themoving direction of the touch gesture is shown. In one exemplaryembodiment, the direction of the touch gesture may be determined usingthe relative coordinate difference between the starting and endingpoints of the touch gesture. The display apparatus 100 does not considerthe starting point or touch point of the touch gesture when selecting aregion. The display apparatus 100 may select a basic selection regionwhen it receives a touch gesture for any point not moving. For example,the basic selection region may be a region corresponding to the B imagesignal corresponding to the middle region.

When the touch gesture moves in the left direction, the x-coordinatedecreases based on the starting coordinates of the touch gesture. Whenthe difference from the ending coordinate is calculated based on thestarting coordinate, the difference (p) of the x-coordinate of the touchgesture is positive. If the difference in x-coordinate is positive, thedisplay apparatus 100 may determine that the touch gesture has shiftedto the left side, and select a region corresponding to the C imagesignal in the left direction. Since the display screen is divided into aleft region and a right region, there is no influence on they-coordinate.

When the touch gesture moves in the right direction, the x-coordinateincreases based on the starting coordinates of the touch gesture. Whenthe difference from the ending coordinate is calculated based on thestarting coordinate, the difference (p) of the x-coordinate of the touchgesture is negative. If the difference in x-coordinate is negative, thedisplay apparatus 100 may determine that the touch gesture has shiftedto the right side, and select a region corresponding to the D imagesignal in the right direction.

As another exemplary embodiment, the display apparatus 100 may determinethe direction of the touch gesture based on the change in the differencebetween the corner coordinates and the touch gesture coordinatesaccording to the movement of the touch gesture. The difference betweenthe corner coordinates and the coordinates of the touch gesturecoordinate can be expressed as an absolute value. As described above,when the touch gesture moves, the difference between the coordinates ofthe touch gesture and the corner coordinates close to the movingdirection is reduced. That is, the display apparatus 100 may determinethat the touch gesture moves toward a corner in the direction in whichthe difference between the coordinates of the touch gesture and thecorner coordinates decreases. For example, if the touch gesture moves inthe left direction, the x-coordinate of the touch gesture decreases.Accordingly, the difference between the x-axis values between theK-corner coordinates or the M-corner coordinates and the touch gesturecoordinates decreases. The display apparatus 100 may determine that thetouch gesture moves in the direction of the K-corner or the M-corner.Accordingly, the display apparatus 100 may select a region correspondingto the C image signal in the left direction. If the touch gesture movesto the right, the x-coordinate of the touch gesture increases.Accordingly, the difference between the x-axis values between theL-corner coordinates or the N-corner coordinates and the touch gesturecoordinates decreases. The display apparatus 100 may determine that thetouch gesture moves in the direction of the L-corner or the N-corner.Accordingly, the display apparatus 100 may select a region correspondingto the D image signal in the right direction. The display apparatus 100may select a basic selection region when it receives a touch gesture forany point not moving. For example, the basic selection region may be aregion corresponding to the B image signal corresponding to the middleregion.

FIGS. 8A and 8B are views for explaining a fifth exemplary embodimentfor selecting one of a plurality of regions.

Referring to FIG. 8A, a screen including a plurality of regionscorresponding to a plurality of image signals is shown. There are threeimage signals, and the C image signal may correspond to the upperregion, the B image signal may correspond to the middle region, and theD image signal may correspond to the lower region.

Referring to FIG. 8B, a table for explaining a method of determining themoving direction of the touch gesture is shown. In one exemplaryembodiment, the direction of the touch gesture may be determined usingthe relative coordinate difference between the starting and endingpoints of the touch gesture. The display apparatus 100 may select abasic selection region when it receives a touch gesture for any pointnot moving. For example, the basic selection region may be a regioncorresponding to the B image signal corresponding to the middle region.

When the touch gesture moves in the upward direction, the y-coordinatedecreases based on the starting coordinates of the touch gesture. Whenthe difference from the ending coordinate is calculated based on thestarting coordinate, the difference (q) of the y-coordinate of the touchgesture is positive. If the difference in y-coordinate is positive, thedisplay apparatus 100 may determine that the touch gesture has shiftedin the upward direction, and select a region corresponding to the Cimage signal in the upward direction. Since the display screen isdivided into an upper region and a lower region, there is no influenceon the x-coordinate.

When the touch gesture moves in the downward direction, the y-coordinateincreases based on the starting coordinates of the touch gesture. Whenthe difference from the ending coordinate is calculated based on thestarting coordinate, the difference (q) of the y-coordinate of the touchgesture is negative. If the difference in y-coordinate is negative, thedisplay apparatus 100 may determine that the touch gesture has shiftedin the downward direction, and select a region corresponding to the Dimage signal in the downward direction.

As another exemplary embodiment, the display apparatus 100 may determinethe direction of the touch gesture based on the change in the differencebetween the corner coordinates and the touch gesture coordinatesaccording to the movement of the touch gesture. When the touch gesturemoves, the difference between the coordinate of the touch gesture andthe corner coordinate near the moving direction is reduced. That is, thedisplay apparatus 100 may determine that the touch gesture moves towarda corner in the direction in which the difference between thecoordinates of the touch gesture and the corner coordinates decreases.For example, if the touch gesture moves in the upward direction, they-coordinate of the touch gesture decreases. Accordingly, the differencebetween the y-axis values between the K-corner coordinates or theL-corner coordinates and the touch gesture coordinates decreases. Thedisplay apparatus 100 may determine that the touch gesture moves in thedirection of the K-corner or the L-corner. Accordingly, the displayapparatus 100 may select a region corresponding to the C image signal inthe upward direction. If the touch gesture moves in the downwarddirection, the y-coordinate of the touch gesture increases. Accordingly,the difference between the y-axis values between the M-cornercoordinates or the N-corner coordinates and the touch gesturecoordinates decreases. The display apparatus 100 may determine that thetouch gesture moves in the direction of the M-corner or the N-corner.Accordingly, the display apparatus 100 may select a region correspondingto the D image signal in the downward direction. The display apparatus100 may select a basic selection region when it receives a touch gesturefor any point not moving. For example, the basic selection region may bea region corresponding to the B image signal corresponding to the middleregion.

FIGS. 9A and 9B are views for explaining a sixth exemplary embodimentfor selecting one of a plurality of regions.

Referring to FIG. 9A, a screen including a plurality of regionscorresponding to a plurality of image signals is shown. There are threeimage signals, and the C image signal may correspond to the left region,the B image signal may correspond to the middle region, and the D imagesignal may correspond to the right region. The display apparatus mayselect one of the plurality of regions by considering the moving lengthof the directional touch gesture.

Referring to FIG. 9B, a process of selecting one region according to themoving length is shown. The display apparatus 100 may determine thedirection of the touch gesture input on the display. Since the processof determining the direction of the touch gesture has been describedabove, the description is omitted herein. The moving length of thedirectional touch gesture may vary. In addition, the display apparatus100 may have at least one threshold depending on the number of dividedregions. For example, as shown in FIG. 9A, when the screen of thedisplay apparatus 100 includes three regions horizontally or vertically,the display apparatus 100 may have two thresholds. When the screen ofthe display apparatus 100 includes four areas horizontally orvertically, the display apparatus 100 may have three thresholds.

As shown in FIGS. 9A and 9B, an exemplary embodiment for selecting aregion when the screen of the display apparatus 100 includes three areasin a horizontal arrangement will be described. The display apparatus 100may determine the direction of the touch gesture as described above. Asshown in FIG. 9B, the display apparatus 100 may determine that the touchgesture moves in the right direction. The display apparatus 100 may havetwo thresholds. In addition, the display apparatus 100 may also considerthe moving length of the touch gesture. If the touch gesture moves inthe x-axis direction to less than a first threshold value 11, thedisplay apparatus 100 may select a region corresponding to the C imagesignal disposed at the leftmost side. If the touch gesture moves in thex-axis direction to greater than the first threshold value 11 and lessthan a second threshold value 12, the display apparatus 100 may select aregion corresponding to the B image signal disposed in the middle. Ifthe touch gesture moves in the x-axis direction to greater than thesecond threshold value 12, the display apparatus 100 may select a regioncorresponding to the D image signal disposed at the rightmost side. Thatis, when the touch gesture moves beyond the (n−1)th threshold value andless than the n-th threshold value in the rightward direction withrespect to the x-axis, the display apparatus 100 may select the n-thregion adjacent to the right side of the (n−1)th region.

FIGS. 10A and 10B are views for explaining a seventh exemplaryembodiment for selecting one of a plurality of regions.

Referring to FIG. 10A, a screen including a plurality of regionscorresponding to a plurality of image signals is shown. There are threeimage signals, and the C image signal may correspond to the left region,the B image signal may correspond to the middle region, and the D imagesignal may correspond to the right region.

Referring to FIG. 10B, a process of selecting one region according tothe moving length is shown. The display apparatus 100 may determine thedirection of the touch gesture input on the display. An exemplaryembodiment for selecting a region when the screen of the displayapparatus 100 includes three regions in a horizontal arrangement will bedescribed. The display apparatus 100 may determine the direction of thetouch gesture as described above. As shown in FIG. 10B, the displayapparatus 100 may determine that the touch gesture moves in the leftwarddirection. The display apparatus 100 may have two thresholds. Inaddition, the display apparatus 100 may also consider the moving lengthof the touch gesture. If the touch gesture moves in the x-axis directionto less than the first threshold value 11, the display apparatus 100 mayselect a region corresponding to the D image signal disposed at therightmost side. If the touch gesture moves in the x-axis direction togreater than the first threshold value 11 and less than a secondthreshold value 12, the display apparatus 100 may select a regioncorresponding to the B image signal disposed in the middle. If the touchgesture moves in the x-axis direction to greater than the secondthreshold value 12, the display apparatus 100 may select a regioncorresponding to the C image signal disposed at the leftmost side. Thatis, when the touch gesture moves beyond the (n−1)th threshold value andless than the n-th threshold value in the leftward direction withrespect to the x-axis, the display apparatus 100 may select the n-thregion adjacent to the left side of the (n−1)th region.

FIGS. 11A and 11B are views for explaining an eighth exemplaryembodiment for selecting one of a plurality of regions.

Referring to FIG. 11A, a screen including a plurality of regionscorresponding to a plurality of image signals is shown. There are threeimage signals, and the C image signal may correspond to the upperregion, the B image signal may correspond to the middle region, and theD image signal may correspond to the lower region.

Referring to FIG. 11B, a process of selecting one region according tothe moving length is shown. The display apparatus 100 may determine thedirection of the touch gesture input on the display. An exemplaryembodiment for selecting a region when the screen of the displayapparatus 100 includes three regions in a vertical arrangement will bedescribed. The display apparatus 100 may determine the direction of thetouch gesture as described above. As shown in FIG. 11B, the displayapparatus 100 may determine that the touch gesture moves in the upwarddirection. The display apparatus 100 may have two thresholds. Inaddition, the display apparatus 100 may also consider the moving lengthof the touch gesture. If the touch gesture moves in the y-axis directionto less than the first threshold value 11, the display apparatus 100 mayselect a region corresponding to the D image signal disposed at thelowest side. If the touch gesture moves in the x-axis direction togreater than the first threshold value 11 and less than the secondthreshold value 12, the display apparatus 100 may select a regioncorresponding to the B image signal disposed in the middle. If the touchgesture moves in the y-axis direction to greater than the secondthreshold value 12, the display apparatus 100 may select a regioncorresponding to the C image signal disposed at the top. That is, whenthe touch gesture moves beyond the (n−1)th threshold value and less thanthe n-th threshold value in the upward direction with respect to they-axis, the display apparatus 100 may select the n-th region adjacent tothe upper side of the (n−1)th region.

FIGS. 12A and 12B are views for explaining a ninth exemplary embodimentfor selecting one of a plurality of regions.

Referring to FIG. 12A, a screen including a plurality of regionscorresponding to a plurality of image signals is shown. There are threeimage signals, and the C image signal may correspond to the upperregion, the B image signal may correspond to the middle region, and theD image signal may correspond to the lower region.

Referring to FIG. 12B, a process of selecting one region according tothe moving length is shown. The display apparatus 100 may determine thedirection of the touch gesture input on the display. An exemplaryembodiment for selecting a region when the screen of the displayapparatus 100 includes three regions in a vertical arrangement will bedescribed. The display apparatus 100 may determine the direction of thetouch gesture as described above. As shown in FIG. 12B, the displayapparatus 100 may determine that the touch gesture moves in the downwarddirection. The display apparatus 100 may have two thresholds. Inaddition, the display apparatus 100 may also consider the moving lengthof the touch gesture. If the touch gesture moves in the y-axis directionto less than the first threshold value 11, the display apparatus 100 mayselect a region corresponding to the C image signal disposed at the top.If the touch gesture moves in the x-axis direction to greater than thefirst threshold value 11 and less than the second threshold value 12,the display apparatus 100 may select a region corresponding to the Bimage signal disposed in the middle. If the touch gesture moves in they-axis direction to greater than the second threshold value 12, thedisplay apparatus 100 may select a region corresponding to the D imagesignal disposed at the lowest side. That is, when the touch gesturemoves beyond the (n−1)th threshold value and less than the n-ththreshold value in the downward direction with respect to the y-axis,the display apparatus 100 may select the n-th region adjacent to thelower side of the (n−1)th region.

The above-described exemplary embodiments are exemplary, and the displayapparatus 100 can configure a plurality of regions corresponding to aplurality of video signals in various formats. In addition, the displayapparatus 100 can select one region in various ways according to theshape of the configured region or the like. A controlling method of adisplay apparatus will be described below.

FIG. 13 is a flowchart illustrating a controlling method of the displayapparatus according to an exemplary embodiment.

The display apparatus receives a plurality of image signals from aplurality of external devices, at operation S1310. The plurality ofexternal devices may be connected to the display apparatus by wire orwirelessly. In addition, the plurality of external devices may transmitthe respective image signals to the display apparatus. The displayapparatus may reconfigure the plurality of image signal received fromthe plurality of external devices.

The display 130 displays a screen including a plurality of regionscorresponding to each of the plurality of image signals, at operationS1320. That is, the display apparatus may divide the screen into aplurality of regions and display images of the received image signals inthe divided regions.

When a directional touch gesture is input on the display, the displayapparatus selects one of the plurality of regions based on the directionof the touch gesture, at operation S1330. When the display apparatusselects one area, the direction of the touch gesture may be calculatedby using the relative coordinates of the starting point and the endingpoint of the directional touch gesture. The display apparatus may alsoselect one of the plurality of regions by considering the moving lengthof the directional touch gesture. That is, the processor 120 does notconsider the starting point of the directional touch gesture.

The display apparatus displays the selected one area in full screen, atoperation S1340. In addition, when the display apparatus receives atouch command on the displayed full screen, the display apparatus maytransmit the touch command to an external device that transmits an imagesignal corresponding to the full screen.

For example, the display apparatus control method may be implemented asa program and stored in a non-transitory computer readable medium.

The non-transitory computer readable medium refers to a medium thatstores data semi-permanently rather than storing data for a very shorttime, such as a register, a cache, a memory or etc., and is readable byan apparatus. In detail, programs for executing the aforementionedvarious methods may be stored in the non-transitory computer readablemedium, for example, a compact disc (CD), a digital versatile disc(DVD), a hard disc, a Blu-ray disc, a universal serial bus (USB), amemory card, a read only memory (ROM), and the like, and may beprovided.

The foregoing embodiments and advantages are merely exemplary and arenot to be construed as limiting. The present teaching can be readilyapplied to other types of apparatuses and processes. Also, thedescription of exemplary embodiments is intended to be illustrative, andnot to limit the scope of the claims, and many alternatives,modifications, and variations will be apparent to those skilled in theart.

What is claimed is:
 1. A display apparatus comprising: a communicationinterface; a display; and a processor configured to: receive, throughthe communication interface, a plurality of image signals from aplurality of external devices, control the display to display aplurality of images in a plurality of regions respectively, each of theplurality of images corresponding to each of the plurality of imagesignals, in response to a touch gesture being input on the display,identify a moving direction of the touch gesture based on a startingpoint and an ending point of the touch gesture on the display, select aregion from among the plurality of regions based on the identifiedmoving direction of the touch gesture, and control the display todisplay the selected region as a full screen.
 2. The apparatus asclaimed in claim 1, wherein the processor is further configured to, inresponse to a touch command being input while the selected region is thedisplayed as the full screen, control the communication interface totransmit the touch command to an external device that transmits an imagesignal of the plurality of image signals corresponding to the fullscreen.
 3. The apparatus as claimed in claim 1, wherein the processor isfurther configured to determine an x-axis value based on a differencebetween an x-coordinate of the starting point of the touch gesture andan x-coordinate of the ending point of the touch gesture, determine ay-axis value based on a difference between a y-coordinate of thestarting point of the touch gesture and a y-coordinate of the endingpoint of the touch gesture, and select the selected region based on thex-axis value and the y-axis value.
 4. The apparatus as claimed in claim3, wherein the processor is further configured to: in a state in whichthe plurality of regions includes three regions respectively arranged ona left side, a right side and a first middle between the left side andthe right side, select a region arranged in the first middle in responseto a touch gesture for selecting one point being input, select a regionarranged on the left side in response to the x-axis value beingpositive, and select a region arranged on the right side in response tothe x-axis value being negative, and in a state in which the pluralityof regions includes three regions arranged on an upper side, a lowerside and a second middle between the upper side and the lower side,select a region arranged in the second middle in response to the touchgesture for selecting the one point being input, select a regionarranged on the upper side in response to the y-axis value beingpositive, and select a region arranged on the lower side in response tothe y-axis value being negative.
 5. The apparatus as claimed in claim 3,wherein the processor is further configured to, in a state in which theplurality of regions includes four regions respectively arranged on anupper left portion, an upper right portion, a lower left portion, and alower right portion, select a region arranged on the upper left portionin response to the x-axis value being positive and the y-axis valuebeing positive, select a region arranged on the upper right portion inresponse to the x-axis value being negative and the y-axis value beingpositive, select a region arranged on the lower left portion in responseto the x-axis value being positive and the y-axis value being negative,and select a region arranged on the lower right portion in response tothe x-axis value being negative and the y-axis value being negative. 6.The apparatus as claimed in claim 3, wherein the processor is furtherconfigured to select the selected region based on a moving length of thetouch gesture.
 7. The apparatus as claimed in claim 6, wherein theprocessor is further configured to: in a state in which the plurality ofregions are arranged in a horizontal arrangement format in a leftdirection and a right direction and the x-axis value is positive, selecta first region arranged on a rightmost side in response to an x-axismoving length being less than a first threshold value, select a secondregion adjacent to a left side of the first region in response to thex-axis moving length being greater than the first threshold value andless than a second threshold value, and select an n region adjacent to aleft side of a (n−1) region in response to the x-axis moving lengthbeing greater than an (n−1) threshold value and less than an n thresholdvalue, and in a state in which a value in the x-axis direction of thetouch gesture is negative, select the n region in response to the x-axismoving length being less than the first threshold value, select the(n−1) region in response to the x-axis moving length being greater thanthe first threshold value and less than the second threshold value, andselect the second region in response to the x-axis moving length greaterthan the (n−1) threshold value and less than the n threshold value.
 8. Acontrolling method of a display apparatus, the controlling methodcomprising: receiving, through a communication interface, a plurality ofimage signals from a plurality of external devices; displaying aplurality of images in a plurality of regions respectively each of theplurality of images corresponding to each of the plurality of imagesignals; in response to a touch gesture being input on the display,identifying a moving direction of the touch gesture based on a startingpoint and an ending point of the touch gesture on the display; selectinga region from the plurality of regions based on the identified movingdirection of the touch gesture; and displaying an image displayed on theselected region as a full screen.
 9. The controlling method as claimedin claim 8, further comprising in response to a touch command beinginput while the selected region is the displayed as the full screen,transmitting the touch command to an external device that transmits animage signal of the plurality of image signals corresponding to the fullscreen.
 10. The controlling method as claimed in claim 8, wherein theselecting comprises determining an x-axis value based on a differencebetween an x-coordinate of the starting point of the touch gesture andan x-coordinate of the ending point of the touch gesture, determining ay-axis value based on a difference between a y-coordinate of thestarting point of the touch gesture and a y-coordinate of the endingpoint of the touch gesture, and selecting the selected region based onthe x-axis value and the y-axis value.
 11. The controlling method asclaimed in claim 10, wherein the selecting comprises: in a state inwhich the plurality of regions includes three regions respectivelyarranged on a left side, a right side and a first middle between theleft side and the right side, selecting a region arranged in the firstmiddle in response to a touch gesture for selecting one point beinginput, selecting a region arranged on the left side in response to thex-axis value being positive, and selecting a region arranged on theright side in response to the x-axis value being negative, and in astate in which the plurality of regions includes three regions arrangedon an upper side, a lower side and a second middle between the upperside and the lower side, selecting a region arranged in the secondmiddle in response to the touch gesture for selecting the one pointbeing input, selecting a region arranged on the upper side in responseto the y-axis value being positive, and selecting a region arranged onthe lower side in response to the y-axis value being negative.
 12. Thecontrolling method as claimed in claim 10, wherein the selectingcomprises, in a state in which the plurality of regions includes fourregions respectively arranged on an upper left portion, an upper rightportion, a lower left portion, and a lower right portion, selecting aregion arranged on the upper left portion in response to the x-axisvalue being positive and the y-axis value being positive, selecting aregion arranged on the upper right portion in response to the x-axisvalue being negative and the y-axis value being positive, selecting aregion arranged on the lower left portion in response to the x-axisvalue being positive and the y-axis value being negative, and selectinga region arranged on the lower right portion in response to the x-axisvalue being negative and the y-axis value being negative.
 13. Thecontrolling method as claimed in claim 10, wherein the selectingcomprises selecting the selected region based on a moving length of thetouch gesture.
 14. The controlling method as claimed in claim 13,wherein the selecting comprises: in a state in which the plurality ofregions are arranged in a horizontal arrangement format arranged in aleft direction and a right direction and the x-axis value is positive,selecting a first region arranged on a rightmost side in response to anx-axis moving length being less than a first threshold value, selectinga second region adjacent to a left side of the first region in responseto the x-axis moving length being greater than the first threshold valueand less than a second threshold value, and selecting an n regionadjacent to a left side of a (n−1) region in response to the x-axismoving length being greater than an (n−1) threshold value and less thanan n threshold value, and in a state in which a value in the x-axisdirection of the touch gesture is negative, selecting the n region inresponse to the x-axis moving length being less than the first thresholdvalue, selecting the (n−1) region in response to the x-axis movinglength being greater than the first threshold value and less than thesecond threshold value, and selecting the second region in response tothe x-axis moving length being greater than the (n−1) threshold valueand less than the n threshold value.
 15. A display apparatus comprising:a communication interface configured to receive a plurality of imagesignals from a plurality of external devices; a display configured todisplay a screen including a plurality of regions respectivelycorresponding to each of the plurality of image signals; and a processorconfigured to determine an x-axis value based on a difference between anx-coordinate of a starting point of a touch gesture and an x-coordinateof an ending point of the touch gesture, determine a y-axis value basedon a difference between a y-coordinate of the starting point of thetouch gesture and a y-coordinate of the ending point of the touchgesture, and select a region from among the plurality of regions basedon the x-axis value and the y-axis value.